An increase in cytoplasmic free calcium ion concentration is thought to play a critical role in the entry of resting T lymphocytes into the mitotic cycle. Not all murine T cells, however, generate such a calcium signal when exposed to mitogenic doses of concanavalin A (Con A), and the proportion of nonresponsive cells increases with age in adult mice. Since the frequency of T cells able to generate cytotoxic or lymphokine-secreting cells in culture also declines in old age, we have speculated that the defect in changes in Ca2+ concentration might underlie this functional deficit. To examine the relationship between functional competence and the calcium signaling pathway, we performed limiting dilution analyses of T cells enriched (by a fluorescence-based cell-sorting method) for high or low calcium signal generation. We found that rapid Ca2+ signal generation after Con A exposure did indeed correlate well with functional competence in Con A-stimulated limiting dilution cultures. Furthermore, selection for Ca2+ signals induced by anti-CD3 antibody, or even by ionomycin, similarly enriched for the functionally competent set of T cells. The ionomycin result, in particular, suggests that the difference between the reactive and nonreactive sets of T cells is unlikely to result simply from alterations in receptor-linked signal transduction pathways. We discuss a model in which immune senescence involves an age-dependent increase in a subset of T cells in which changes in cytoplasmic Ca2+ concentration are relatively difficult to induce by either receptor-dependent mitogens or ionophores.